鄂尔多斯盆地华庆地区长8段油藏高电阻率水层识别方法

doi:10.3969/j.issn.1672-7703.2020.06.013

摘要/Abstract

摘要： 鄂尔多斯盆地华庆地区长8 段油藏为典型的低孔、低渗油藏，储层物性差、填隙物含量高，普遍发育高电阻率水层，测井解释符合率低，流体性质判识困难。对华庆地区长8 段高电阻率水层成因进行分析，结果表明：区域内绿泥石膜含量偏高，绿泥石膜吸附沥青质形成的沥青质油膜卡断孔隙，使导电路径复杂，形成“油包水”现象，并伴随区域内的低矿化度地层水，最终导致水层电阻率升高。高电阻率水层的测井响应特征为电阻率曲线高值、形态呈 “凹形”，物性较高值（渗透率大于1mD、孔隙度大于15%）；油层的测井响应特征为电阻率曲线高值、形态呈“凸形”，物性低值（渗透率小于1mD、孔隙度小于15%）。根据高电阻率水层的测井曲线响应特征、岩石物理特征和成因机理，分别构建区分曲线形态图版法、绿泥石膜含量—电阻率交会图法、电阻率—孔隙度相关性分析法。建立的识别方法解决了华庆地区长8 段油藏高电阻率水层识别难题，各方法的测井解释符合率均提高到80% 以上。

关键词: 华庆地区, 高电阻率水层, 成因分析, 识别方法

Abstract: The oil reservoir in the Chang 8 member in the Huaqing area of the Ordos Basin is a typical low-porosity and low-permeability reservoir. It has poor physical properties, high content of interstitial materials, and a generally developed high-resistivity water layer. The coincidence rate of well logging interpretation is low, and identification of fluid properties is difficult. Causation analysis of the high-resistivity water layer indicates a high content of chlorite membrane in the study area. An asphaltene oil film is formed when asphaltene is adsorbed by the chlorite membrane, which blocks the pores, complicates the conductive path, and causes the phenomenon of “water in oil”. When combined with low-salinity formation water in the area, the resistivity of the water layers eventually becomes high. The well logging response of high-resistivity water layers is characterized by a high resistivity curve with a concave shape and high values for physical properties (permeability >1 mD, and porosity>15%). The well logging response of oil layers is characterized by a high resistivity curve with a convex shape and low values for physical properties (permeability <1 mD and porosity <15%). The petrophysical properties and formation mechanism of high-resistivity water layers can be determined from well logging response characteristics and identification methods such as a chart distinguishing curve morphology, a cross-plot of chlorite membrane content and resistivity, and correlation analysis of resistivity-porosity. These identification methods have solved the problem of high-resistivity water layer identification in the oil reservoir in the Chang 8 member, with the coincidence rate of well logging interpretation for each method increasing to more than 80%.

中图分类号:

张少华, 周金昱, 陈刚, 冯伊涵, 李卫兵, 王长胜, 席辉. 鄂尔多斯盆地华庆地区长8段油藏高电阻率水层识别方法[J]. 中国石油勘探, 2020, 25(6): 118-128.

Zhang Shaohua, Zhou Jinyu, Chen Gang, Feng Yihan, Li Weibing, Wang Changsheng, Xi Hui. Identification method for high-resistivity water layer in the oil reservoir in the Chang 8 member, Huaqing area, Ordos Basin[J]. China Petroleum Exploration, 2020, 25(6): 118-128.

参考文献

[1] 邱启红，夏朝辉，张铭，等．印尼XX 区块高阻水层成因分析[J]. 海洋石油，2012,32(14):75-78. Qiu Qihong, Xia Zhaohui, Zhang Ming, et al. Analysis of the origin of high resistivity water layer in XX block of Indonesia[J]. Offshore Oil, 2012, 32(14):75-78.
[2] 周荣安，焦创赟，李志伟，等．鄂尔多斯盆地高电阻率水层的成因分析[J]. 测井技术，2005,29(4):333-336. Zhou Rong’an, Jiao Chuangyun, Li Zhiwei, et al. On genesis of high resistivity water formation in Ordos Basin[J]. Well Logging Technology, 2005,29(4):333-336.
[3] 冯春珍，韩世峰，吴勇，等．某地区长8 中高电阻率储层出水原因分析及其应用[J]. 测井技术，2007,31(4):347-353. Feng Chunzhen, Han Shifeng, Wu Yong, et al. Causation analysis of water-out from a Chang-8 high resistivity formation and its application[J]. Well Logging Technology, 2007,31(4):347-353.
[4] 吴应忠，段毅，赵阳，等．陇东地区长81 低阻油层与高阻水层识别标准研究[J]. 特种油气藏，2017,24(1):38-42. Wu Yingzhong, Duan Yi, Zhao Yang, et al. Standards for discernment of low-resistivity oil zones and high-resistivity water zones in L81 formation of the Longdong area[J]. Special Oil and Gas Reservoirs, 2017,24(1):38-42.
[5] 石玉江，毛志强，冯程，等．低渗透复杂润湿性储层岩石物理实验、测井响应机理与高阻水层识别[C]//2017 油气田勘探与开发国际会议论文集，2017. Shi Yujiang, Mao Zhiqiang, Feng Cheng, et al. Study on petrophysical experiments, log response mechanism, high resistivity oil and water layer identification in low-permeability reservoirs with complex wettability[C]//International Field Exploration and Development Conference 2017.
[6] 李晓辉，张美玲，谭辉红．高电阻率水层定性识别方法研究[J]. 测井技术，2000,24( 增刊1):491-493. Li Xiaohui, Zhang Meiling, Tan Huihong. On qualitative identification of water layers with high resistivity[J]. Well Logging Technology, 2000,24(S1):491-493.
[7] 张庆国，王硕，冯小东，等．大情字井油田高阻水层成因分析与识别方法[J]. 科学技术与工程，2011,11(34):8444-8451. Zhang Qingguo, Wang Shuo, Feng Xiaodong, et al . On genesis of high resistivity water formation and identification in Daqingzi Oilfield[J]. Science Technology and Engineering, 2011,11(34):8444-8451.
[8] 张美玲，吕鑫淼，张士奇．结合沉积成藏规律实现葡萄花疑难层测井解释[J]. 大庆石油地质与开发，2016,35(1):140-144. Z h a n g M e i l i n g , Lü X i n m i a o , Z h a n g S h i q i . L o g g i n g interpretation of the difficult Putaohua reservoirs integrated with the sedimentary and accumulating laws[J]. Petroleum Geology and Oilfield Development in Daqing, 2016,35(1):140-144. [9] 冯琼，陈新民，李争，等．塔中4 油田CⅠ油组高阻水层成因分析及油层解释方法研究[J]. 江汉石油学院学报，2001,23( 增刊1):38-40. Feng Qiong, Chen Xinmin, Li Zheng, et al. Genetic analysis of high resistive aqueous layer and reservoir interpretation of sand-set C1 in Tazhong 4 Oilfield[J]. Journal of Jianghan Petroleum Institute, 2001,23(S1):38-40.
[10] 朱轶，史鸿祥，高春海，等．塔北中部地区奥陶系一间房组高电阻率地层成因及评价意义[J]. 录井工程，2012,23(3):76-79. Zhu Yi, Shi Hongxiang, Gao Chunhai, et al. Causes of high resistivity pay zone and evaluation significance for Yijianfang Formation of Ordovician in central Tabei area[J]. Mud Logging Engineering, 2012,23(3):76-79.
[11] 黄东，汪华，陈利敏，等．中国南方地区碳酸盐岩储层高电阻率水层地质成因：以川西地区下二叠统栖霞组为例[J]. 天然气工业， 2012,32(11):22-26. Huang Dong, Wang Hua, Chen Limin, et al. Geologic origin of aquifer with high resistivity in the carbonate reservoirs in South China: a case study from the Lower Permian Qixia formation in West Sichuan Basin[J]. Natural Gas Industry, 2012,32(11):22-26.
[12] 冯程，毛志强，石玉江，等. 测井曲线相关性分析及其在复杂润湿性油层识别中的应用[J]. 科学技术与工程，2015,15(21):117-122. Feng Cheng, Mao Zhiqiang, Shi Yujiang, et al. Correlation analysis of well logs and its application to identifying pay zones with complex wettability[J]. Science Technology and Engineering, 2015,15(21):117-122.
[13] 邓秀琴，付金华，姚泾利，等．鄂尔多斯盆地中及上三叠统延长组沉积相与油气勘探的突破[J]. 古地理学报，2011,13(4)：443-447. Deng Xiuqin, Fu Jinhua, Yao Jingli, et al. Sedimentary facies of the Middle-Upper Triassic Yanchang Formation in Ordos Basin and breakthrough in petroleum exploration[J]. Journal Of Palaeogeography, 2011,13(4):443-447.
[14] 张少华，石玉江，陈刚，等．鄂尔多斯盆地姬塬地区长61 低对比度油层识别方法与产水率分级评价[J]. 中国石油勘探，2018,23(1):71-80. Zhang Shaohua, Shi Yujiang, Chen Gang, et al. Identification methods and water productivity classification evaluation of low contrast Chang 61 oil reservoirs in Jiyuan area, Ordos Basin[J]. China Petroleum Exploration, 2018,23(1):71-80.
[15] 孙建博，孙兵华，赵谦平，等．鄂尔多斯盆地富县地区延长组长7 湖相页岩油地质特征及勘探潜力评价[J]. 中国石油勘探，2018,23(6):29-37. Sun Jianbo, Sun Binghua, Zhao Qianping, et al. Geological characteristics and exploration potential evaluation of Chang 7 lacustrine shale oil in Yanchang Formation, Fuxian area, Ordos Basin[J]. China Petroleum Exploration, 2018,23(6):29-37.
[16] 付金华，范立勇，刘新社，等．鄂尔多斯盆地天然气勘探新进展、前景展望和对策措施[J]. 中国石油勘探，2019,24(4):418-430. Fu Jinhua, Fan Liyong, Liu Xinshe, et al. New progresses, prospects and countermeasures of natural gas exploration in the Ordos Basin[J]. China Petroleum Exploration, 2019,24(4):418-430.
[17] 张春林，李剑，刘锐娥．鄂尔多斯盆地盒8 段致密砂岩气储层微观特征及其形成机理[J]. 中国石油勘探，2019,24(4):476-484. Zhang Chunlin, Li Jian, Liu Rui’e. Microscopic characteristics and forming mechanisms of He 8th member tight sandstone gas reservoirs in Ordos Basin[J]. China Petroleum Exploration, 2019,24(4):476-484.
[18] 包洪平，黄正良，武春英，等．鄂尔多斯盆地中东部奥陶系盐下侧向供烃成藏特征及勘探潜力[J]. 中国石油勘探，2020,25(3):134-145. Bao Hongping, Huang Zhengliang, Wu Chunying, et al . Hydrocarbon accumulation characteristics and exploration potential of Ordovician pre-salt formations by lateral hydrocarbon supply in the central-eastern Ordos Basin[J]. China Petroleum Exploration, 2020,25(3):134-145.
[19] 陈世加，路俊刚，姚泾利，等．鄂尔多斯盆地华庆地区长8 油层组成藏特征及控制因素[J]. 沉积学报，2012,20(6):1130-1139. Chen Shijia, Lu Jungang, Yao Jingli, et al. Characteristics of reservoir formation and the controlling factors of Chang 8 Oil-bearing formation in Huaqing area of Ordos Basin[J]. Acta Sedimentologica Sinica, 2012,20(6):1130-1139.
[20] 张纪智，陈世加，肖艳，等．鄂尔多斯盆地华庆地区长8 致密砂岩储层特征及其成因[J]. 石油天然气地质，2013,34(5):679-684. Zhang Jizhi, Chen Shijia, Xiao Yan, et al. Characteristics and their genesis of the Chang 8 tight sandstone reservoirs genesis in Huaqing area，Ordos Basin[J]. Oil & Gas Geology, 2013,34(5):679-684.
[21] 赵靖周，白玉彬，曹青，等．鄂尔多斯盆地准连续型低渗透：致密砂岩大油田成藏模式[J]. 石油天然气地质，2012,33(6):811-827. Zhao Jingzhou, Bai Yubin, Cao Qing, et al. Quasi-continuous hydrocarbon accumulation: a new pattern for large tight sand oilfields in the Ordos Basin[J]. Oil & Gas Geology, 2012,33（6）： 811-827.
[22] Archie G E. The electrical resistivity log as an aid in determining some reservoir of characteristics[J]. Petroleum Technology, 1942:54-60.
[23] 陈希孺．概率论与数理统计[M]. 北京：科学出版社，2000,133-140. Chen Xiru. Probability theory ＆ mathematical statistics[M]. Beijing: Science Press，2000,133-140.